JP5529933B2 - Ice maker - Google Patents

Description

  The present invention relates to an ice maker.

  Generally, a refrigerator is a household electrical appliance that allows food and drinks to be stored at a low temperature in an internal storage space shielded by a door. The refrigerator can store food and drink stored in the storage space in a refrigerated or frozen state by cooling the inside of the storage space using cold air generated through heat exchange with the refrigerant circulating in the refrigeration cycle. Configured as follows.

  An ice maker for making ice can be provided inside the refrigerator. The ice maker is configured such that water supplied from a water supply source or a water tank is stored in an ice tray to produce ice. In addition, the ice maker is configured to be able to transfer ice that has been made from the ice tray by a heating method or a twisting method.

  As described above, the ice maker that automatically supplies and transfers ice is formed so as to open upward, and has a structure for pumping the formed ice. And the ice made from the ice maker of such a structure comes to produce the ice which has at least one flat surface, such as a crescent shape or a cubic shape.

  On the other hand, when the shape of the ice is formed in a spherical shape, the ice can be used more conveniently and a different feeling of use can be provided to the user. In addition, when storing the produced ice, it is possible to minimize the sticking of the ice by minimizing the area where the ice contacts.

  On the other hand, Patent Document 1 discloses an ice making machine that can make a three-dimensional ice such as a ball shape or a spherical shape by a separable plate ice making machine.

  However, the ice making machine of Patent Document 1 is a manual type ice making machine, and spherical ice must be manufactured by manual operation, which causes inconvenience in use and also has a problem that the ice making amount is insufficient. .

  The ice making machine of Patent Document 2 is an automatic ice making device, an ice making tray, a cover tray that is movably provided to form an ice making space by coupling with the ice making tray, and a drive unit that rotates the ice making tray. ,including. Although the ice making device having such a structure can automatically make ice, there is a problem that water supply and ice transfer for ice making are not performed smoothly.

Japanese Unexamined Patent Publication No. 2008-170086 Korean Published Patent No. 2011-0037609

  An object of the present invention is to provide an ice maker capable of making spherical ice and preventing them from sticking to each other when storing the produced ice.

  An object of the present invention is to provide an ice maker that can make spherical ice with automatically supplied water and then transfer the ice.

  In order to achieve the above object, an ice maker according to the present invention includes an upper plate tray having an upper shell and a lower plate tray having a lower shell that is in close contact with the upper shell and forms a spherical shell. And one of the upper plate tray and the lower plate tray is separated from the other one, or one of the upper plate tray and the lower plate tray is in close contact with the other one. A drive unit for providing power for the above and an ejecting unit provided on one side of the tray member for separating ice formed in the spherical shell, the upper tray and the Any one of the lower plate trays is formed to linearly move in the vertical direction by the driving unit.

  According to the embodiment proposed from the present invention, when water is supplied in a state where the upper plate tray and the lower plate tray are closed, ice is formed inside a number of shells forming a spherical space. Accordingly, spherical ice can be produced, and the area where the ice contacts with each other can be minimized when the ice is stored, so that the ice can be prevented from sticking, so that storage and convenience in use are improved. The effect can be expected.

  And, it has a structure in which a part of the upper plate tray is joined while being inserted into the lower plate tray, and this makes it possible to make ice close to a perfect sphere in the shell, thereby improving the ice making performance You can expect.

  The ejecting unit provided above the upper tray can minimize the heat generation due to the ice maker's ice transfer, thereby improving the cooling performance and power consumption.

  Further, since the ice can be transferred by the moved ejector, there is an advantage that a more reliable ice transfer operation can be performed by performing a mechanical ice transfer.

1 is a perspective view of a refrigerator according to a first embodiment of the present invention. It is a figure which shows the shape by which the door of a refrigerator is open | released. 1 is a perspective view of an ice maker according to a first embodiment of the present invention. It is a top view of the upper-plate tray by 1st Example of this invention. It is sectional drawing by 5-5 'of FIG. It is a top view of the lower-plate tray by 1st Example of this invention. It is sectional drawing which shows the shape of the cross section by 7-7 'of FIG. It is a sectional side view of an ice maker which shows the state where an upper plate tray is combined with a lower plate tray. It is a sectional side view which shows the state of the ice maker in a water supply state. It is a figure which shows operation | movement of an ice tray sequentially. It is a figure which shows operation | movement of an ice tray sequentially. It is a figure which shows operation | movement of an ice tray sequentially. It is a figure which shows operation | movement of an ice tray sequentially. It is a disassembled perspective view which shows the ice-transfer process of the ice maker by 2nd Example of this invention. It is a disassembled perspective view which shows the ice-transfer process of the ice maker by 2nd Example of this invention. It is a disassembled perspective view which shows the ice-transfer process of the ice maker by 2nd Example of this invention. It is a disassembled perspective view of the ice maker by 3rd Example of this invention. It is a figure which shows sequentially the state by which ice is transferred from an ice maker. It is a figure which shows sequentially the state by which ice is transferred from an ice maker. It is a figure which shows sequentially the state by which ice is transferred from an ice maker. It is a disassembled perspective view of the ice maker by the 4th example of the present invention. It is a top view which shows the coupling | bonding relationship of the drive unit and ejecting unit of an ice maker. It is sectional drawing by 23-23 'of FIG. It is a figure which shows sequentially the state by which ice is transferred from an ice maker. It is a figure which shows sequentially the state by which ice is transferred from an ice maker. It is a figure which shows sequentially the state by which ice is transferred from an ice maker. It is a perspective view of the ice maker by 5th Example of this invention. It is a figure which shows sequentially the state by which ice is transferred from the ice maker of this invention. It is a figure which shows sequentially the state by which ice is transferred from the ice maker of this invention. It is a figure which shows sequentially the state by which ice is transferred from the ice maker of this invention. It is a figure which shows sequentially the state by which ice is transferred from the ice maker of this invention. It is a figure which shows sequentially the state by which ice is transferred from the ice maker by 6th Example of this invention. It is a figure which shows sequentially the state by which ice is transferred from the ice maker by 6th Example of this invention. It is a figure which shows sequentially the state by which ice is transferred from the ice maker by 6th Example of this invention.

  FIG. 1 is a perspective view of a refrigerator according to a first embodiment of the present invention, and FIG. 2 is a diagram illustrating a shape in which a door of the refrigerator is opened.

  1 and 2, the refrigerator 1 according to the first embodiment of the present invention has an outer shape formed by a cabinet 2 that forms a storage space and a door that opens and closes the storage space. Hereinafter, among various types of refrigerators, an example of a bottom freezer type refrigerator in which a freezing room is located below a refrigerating room and the refrigerating room is formed by a pair of rotating doors (what is called french door). Will be described. However, the ice maker according to the embodiment of the present invention is not limited to the presented type of refrigerator, but can be provided for various types of refrigerators.

  Specifically, the cabinet 2 forms a storage space that is partitioned vertically by a barrier, a refrigerator compartment 3 is formed at the top, and a freezer compartment 4 is formed at the bottom. Storage members such as drawers, shelves, and baskets may be provided inside the refrigerator compartment 3 and the freezer compartment 4.

  The door includes a refrigerator compartment door 5 that shields the refrigerator compartment 3 and a refrigerator compartment door 6 that shields the freezer compartment 4. The refrigerator compartment door 5 may be formed by a pair of left and right doors, and the refrigerator compartment 3 can be selectively opened and closed by turning. And the freezer compartment door 6 may be comprised so that it can open and close like a drawer.

  The refrigerator compartment door 5 may be provided with a dispenser 7 for taking out purified water or iced ice to the outside. The dispenser 7 is configured to communicate with an ice maker 100 described below or a structure in which ice produced by the ice maker 100 is stored, and the ice produced can be discharged to the outside via the dispenser 7. May be.

  On the other hand, the freezer compartment 4 is provided with an ice maker 100. The ice maker 100 makes water to be supplied and is formed so that spherical ice is made. An ice bank 102 may be further provided below the ice maker 100 to store the ice made after the ice maker 100 is transferred from the ice maker 100. The ice maker 100 and the ice bank 102 are provided in a separate case 101. You may mount | wear with the inside of the freezer compartment 4 in the accommodated state.

  3 is a perspective view of an ice maker according to the first embodiment of the present invention, FIG. 4 is a plan view of an upper plate tray according to the first embodiment of the present invention, and FIG. 5 is according to 5-5 ′ of FIG. FIG. 6 is a plan view of the lower tray according to the first embodiment of the present invention, FIG. 7 is a sectional view showing the shape of a section taken along 7-7 ′ of FIG. 6, and FIG. It is a sectional side view of an ice maker which shows the state where a board tray is combined with a lower board tray.

  Referring to FIGS. 3 to 8, the ice maker 100 according to the first embodiment of the present invention generally includes a tray that provides a space in which water is supplied and ice is formed, and a driving unit for opening and closing the tray. 130, including an ejecting unit 150 for transferring ice made from the tray. The tray includes an upper plate tray 110 having an upper shape and a lower plate tray 120 having a lower shape.

  More specifically, the upper plate tray 110 may be formed of a metal material having excellent thermal conductivity such as aluminum, a fixed portion 111 fixedly mounted on one side of the freezer compartment 4, and a spherical shape. You may comprise the insertion tray part 112 in which the upper shell 115 for forming the upper half part of ice is formed.

  The fixing portion 111 is formed so as to be attached to the wall surface of the freezer compartment 4 or the side surface of the case 101 of the ice maker 100. The fixed portion 111 is formed with a water supply portion 114 provided with a water supply passage 113 for supplying water for making ice to the lower plate tray 120. The water supply unit 114 is provided at a position communicating with the water supply guide unit 124 formed on the lower plate tray 120, and the water supplied through the water supply channel 113 is supplied to the water supply guide unit 124 of the lower plate tray 120.

  The insertion tray portion 112 is formed in a square shape when viewed from above, and is formed long in the vertical direction. The insertion tray portion 112 is formed so that the upper surface is opened, and an upper shell 115 is formed on the lower surface of the insertion tray portion 112.

  And the lower part of the outer side surface of the insertion tray part 112 is formed in a shape corresponding to the tray accommodating part 123 described below. That is, it is formed so as to incline in a direction in which the width becomes narrower toward the lower side after extending vertically from the lower end of the insertion tray portion 112 to a predetermined length.

  The upper shell 115 is formed in a hemispherical shape, and is combined with the lower shell 122 formed on the lower plate tray 120 to form a spherical shell 103 in which spherical ice is made. Thus, the upper shell 115 forms the upper half of the ice to be made.

  A plurality of upper shells 115 may be arranged in a row or in a row, and an air hole 116 may be formed at the upper end of the upper shell 115. Accordingly, when water is supplied in a state where the upper shell 115 and the lower shell 122 are coupled, the air inside the spherical shell 103 can be discharged to the outside.

  On the other hand, a lower plate tray 120 is provided below the upper plate tray 110. The lower plate tray 120 may be formed of the same metal material as the upper plate tray 110, and a recess 121 in which the water for making ice is added to accommodate the upper shell 115 is formed.

  A rack gear 140 for vertically moving and rotating the lower plate tray 120 is formed on both the left and right sides of the lower plate tray 120. Accordingly, the lower plate tray 120 is provided so as to be movable and rotatable up and down from below the upper plate tray 110.

  A hemispherical lower shell 122 recessed in a hemispherical shape is formed at the lower end of the recess 121, and the upper shell 115 is in close contact with the upper end of the lower shell 122 to form the spherical shell 103. The lower shell 122 may be disposed symmetrically with the upper shell 115.

  On the other hand, a tray accommodating portion 123 into which the insertion tray portion 112 of the upper plate tray 110 is inserted is formed in the concave portion 121. When the lower plate tray 120 moves upward and comes into close contact with the upper plate tray 110, the insertion tray portion 112 is inserted into the tray accommodating portion 123. Then, the upper shell 115 and the lower shell 122 are coupled at an accurate position.

  A water supply guide portion 124 is formed at the center of the tray accommodating portion 123. The water supply guide portion 124 is a portion to which water is supplied via the water supply portion 114 of the upper plate tray 110, protrudes rearward from the upper outer peripheral surface of the recess 121, and is formed at the center of the upper rear surface of the lower plate tray 120. Accordingly, the water flowing into the water supply guide part 124 is guided to the inside of the recess 121, and water is added to the lower shell 122 while flowing in the left and right directions.

  At this time, water supplied to the inside of the recess 121 is added to a level higher than the upper end surface of the lower shell 122, and water is supplied from the inside of the spherical shell 103 formed when the upper plate tray 110 is closed through the air hole 116. Water may be supplied to such an extent that it does not spill. The supplied water is adjusted so as to be supplied in an amount corresponding to a water level slightly lower than the upper end portion of the spherical shell 103 in consideration of an increase in volume during freezing.

  Further, the upper plate tray 110 and the lower plate tray 120 are further provided with an ejecting unit for separating the produced ice from the tray. The ejecting unit 150 includes an upper heater 151 provided on the outer peripheral surface of the upper plate tray 110 and a lower heater 152 provided on the outer peripheral surface of the lower plate tray 120. Specifically, the upper heater 151 and the lower heater 152 are mounted on the outer peripheral surfaces of the upper shell 115 and the lower shell 122, respectively.

  On the other hand, the ice maker 100 is provided with a drive unit 130 for vertically moving and rotating the lower plate tray 120. The drive unit 130 includes a motor 131 that generates rotational power, a drive shaft 132 coupled to the rotation shaft of the motor 131, a pair of pinion gears 133 fitted to the drive shaft 132, and a rack gear 140 that interlocks with the pinion gear 133. Including. The rack gear 140 is mounted on both side surfaces of the lower plate tray 120. The rack gear 140 may be formed integrally when the lower plate tray 120 is formed, or may be mounted on the left and right sides of the lower plate tray 120 after being formed of another material.

  In front of the rack gears 140 on both the left and right sides, pinion gears 133 that can be gear-coupled to the rack gears 140 are provided. The pinion gears 133 are connected to the drive shaft 132 and rotate together with the motor 131.

  The rack gear 140 will be described in more detail. The rack gear 140 includes a vertical portion 141 formed to extend in the vertical direction, and a rotating portion 142 that rounds at a predetermined curvature at the upper end of the vertical portion 141. A gear that meshes with the pinion gear 133 is formed on the outer peripheral surface of the rack gear 140.

  Specifically, the vertical portion 141 is for guiding the vertical movement of the lower plate tray 120 and is formed with a predetermined length in the vertical direction. Accordingly, when the pinion gear 133 is located at the lower end of the vertical portion 141, the lower plate tray 120 comes to the uppermost position and is completely in close contact with the upper plate tray 110. When the pinion gear 133 is positioned at the upper end of the vertical portion 141, the lower plate tray 120 is positioned at a point farthest from the upper plate tray 110 to the lower side.

  In addition, the rotating part 142 may be formed by rounding in a semicircular shape or a fan shape at the upper end part of the vertical part 141, or may be formed to have the same width as the vertical part 141. Therefore, when the pinion gear 133 is further rotated with the pinion gear 133 positioned at the upper end of the vertical portion 141, the pinion gear 133 moves along the rotating portion 142, and the lower plate tray 120 rotates.

  FIG. 9 is a side sectional view showing the state of the ice maker in the water supply state.

  First, referring to FIG. 8, the lower plate tray 120 moves downward, and water supply for ice making is performed while being separated from the upper plate tray 110. At this time, the supplied water is supplied so as to spill from the lower shell 122 as shown in FIG. 8, and an amount slightly smaller than the volume of the spherical shell 103 may be supplied in consideration of expansion of the volume in the ice making process. In the process of inserting the upper plate tray 110 into the lower plate tray 120, the water added to the upper end of the lower shell 122 flows into the upper shell 115.

  Referring to FIG. 9, in a state where the lower plate tray 120 is completely adhered to the upper plate tray 110, the upper shell 115 and the lower shell 122 are completely adhered, water is added to the inside of the upper shell 115, and water leaks. Is cut off.

  Specifically, a stepped portion 112 a is formed at the lower end of the upper tray 110, that is, the lower end of the insertion tray portion 112, and the stepped portion 112 a is seated tightly on the tray accommodating portion 123 of the recess 121.

  Hereinafter, the operation of the ice maker according to the first embodiment of the present invention having the above-described configuration will be described.

  10 to 13 are diagrams sequentially showing the operation of the ice tray.

  Referring to FIGS. 10 to 13, the rack gear 140 has a guide groove 143 for guiding the movement of the lower plate tray 120, and is formed on the side of the ice maker case 101 or the side of the freezer compartment 4 corresponding to the guide groove 143. A guide protrusion 144 may be formed.

  Specifically, the guide protrusion 144 is housed inside the guide groove 143 and guides the lower plate tray 120 to move only in the set path when the lower plate tray 120 moves. Further, about three guide protrusions 144 are arranged vertically at equal intervals, and guide the rotation as well as the vertical movement of the lower plate tray 120. It will be made clear that there is no limit to the number of guide protrusions 144.

  The guide groove 143 is formed by being recessed on the side surface of the rack gear 140, and the first guide groove 143 a formed along the vertical portion 141, the second guide groove 143 b formed along the rotating portion 142, and the first guide groove. The third guide groove 143c may be branched from one side of the 143a and extended outward.

  Meanwhile, a guide roller 134 is further provided on one side of the rack gear 140. The guide roller 134 is included in the drive unit 130 and makes the rack gear 140 move smoothly. In particular, it is brought into close contact with the lower surface of the rotating part 142 and serves as a rotating shaft of the rack gear 140. The guide roller 134 may be rotatably mounted on the wall surface of the freezer compartment 4 or one side surface of the case 101, and is formed so as to correspond to the inner shape of the rotating portion 142.

  Since the ice maker 100 is making ice, the lower plate tray 120 is moved to the lowest position as shown in FIG. At this time, the pinion gear 133 is positioned at the upper end of the vertical portion of the rack gear 140. In such a state, the lower plate tray 120 and the upper plate tray 110 are separated from each other, and can be supplied with water as shown in FIG. The water supplied to the water supply guide unit 124 may fill the lower shell 122 and may be supplied in such an amount as to make spherical ice.

  When water supply to the lower plate tray 120 is completed, the pinion gear 133 rotates counterclockwise by driving the motor 131 to move the rack gear 140 upward. Accordingly, the lower plate tray 120 coupled to the rack gear 140 is moved upward. The lower plate tray 120 is moved upward by the operation of the drive unit 130, and the upper plate tray 110 and the lower plate tray 120 are brought into close contact with each other. When the upper plate tray 110 and the lower plate tray 120 are completely brought into close contact with each other, the driving of the motor 131 is stopped, and the pinion gear 133 is positioned at the lower end of the vertical portion of the rack gear 140 as shown in FIG.

  In such a state, the upper shell 115 and the lower shell 122 are coupled to each other, and the spherical shell 103 is filled with an amount of water necessary for ice making. Then, by the continuous supply of cold air, spherical ice is formed inside the spherical shell 103.

  After a predetermined time has elapsed, the lower heater 152 provided in the lower plate tray 120 first generates heat for ice transfer. When the lower plate tray 120 is heated by the lower heater 152, the lower surface of the ice made is melted.

  In this state, the rotation of the motor 131 causes the pinion gear 133 to rotate counterclockwise, and the rack gear 140 moves downward. Then, as shown in FIG. 12, the pinion gear 133 rotates until it is positioned at the upper end of the vertical portion 141 of the rack gear 140. At this point, the lower plate tray 120 is moved to the lowermost position, and the produced ice is hung on the upper plate tray 110.

  As described above, while the lower plate tray 120 moves only in the vertical direction, the guide protrusion 144 relatively moves in the vertical direction along the first guide groove 143a. Accordingly, the lower plate tray 120 is stably moved in the vertical direction by the guide of the guide protrusion 144 and the first guide groove 143a.

  When the motor 131 further rotates in the state as shown in FIG. 12, the pinion gear 133 further rotates clockwise, and the rotation of the pinion gear 133 causes the rack gear 140 to mesh with the rotating part 142 beyond the vertical part 141. Become. Accordingly, the rack gear 140 rotates counterclockwise, and the lower plate tray 120 also rotates counterclockwise.

  When the rack gear 140 is completely rotated by the rotation of the pinion gear 133, the state shown in FIG. Such a state is a state in which the lower plate tray 120 is moved to the rear of the upper plate tray 110 by the rotation of the rack gear 140, and the lower space of the upper plate tray 110 is completely opened.

  In such a state, the remaining water remaining in the lower shell 122 of the lower plate tray 120 can be discharged and does not interfere with the ice falling from the upper plate tray 110. The ice hanging on the upper plate tray 110 is dropped by the heat generated by the upper heater 151 provided on the upper plate tray 110. Specifically, when the upper heater 151 generates heat in the state as shown in FIG. 13, the upper plate tray 110 is heated and the surface of the ice made in contact with the upper shell 115 is melted. When the surface of the ice melts, the ice falls downward due to its own weight and is stored in the ice bank 102 away from the tray.

  After the ice transfer is completed, the drive unit 130 is moved in the opposite direction, and the lower plate tray 120 is advanced from the water supply for ice making again in the state as shown in FIG. 12 where the lower plate tray 120 is positioned vertically below the upper plate tray 110. The process will be repeated. Here, another means may be further provided so that residual water falling when the lower plate tray 120 rotates does not fall into the ice bank 102. For example, another residual water guide plate is provided on the top of the ice bank 102 so that the residual water does not fall into the ice bank 102, and the residual water guide plate is detached from the ice falling path immediately before the upper heater 151 is operated. It may be.

  The present invention can be applied to various embodiments other than the above-described embodiments, and the second embodiment of the present invention will be described below.

  In the second embodiment of the present invention, an ejecting unit is provided above the upper plate tray, and the ejecting unit is configured to operate in conjunction with driving of the drive unit so that the ice can be transferred downward. It is characterized by.

  Accordingly, the configuration of the ejecting unit and the other configurations except for the coupling relationship between the ejecting unit and the drive unit are all the same as in the first embodiment of the present invention described above, and the same reference numerals are used for the same configurations. Detailed description thereof will be omitted. Reference numerals not shown in the figure indicate the same reference numerals in the above-described embodiments.

  14 to 16 are exploded perspective views showing an ice maker ice-transfer process according to the second embodiment of the present invention.

  Referring to FIGS. 14 to 16, an ice maker 200 according to a second embodiment of the present invention includes an upper plate tray 110 having an upper shell 115 and fixedly mounted on the ice maker case 101 or the freezer compartment 4, and an upper plate tray. 110, a lower plate tray 120 having a lower shell 122 that forms a spherical shell 103, a drive unit 130 for moving and rotating the lower plate tray 120 in the vertical direction, and ice making ice to the outside of the tray assembly. An ejecting unit 250 for transferring ice is included. The ejecting unit 250 includes a disk 251, a load 252, and an ejector 253.

  Specifically, the disk 251 is formed in a disk shape and is coupled to a drive shaft 132 that is rotated by a motor 131. The load 252 is for converting the rotational movement of the disk 251 into the linear movement of the ejector 253, and is formed with a predetermined length, and both ends thereof are axially coupled to the disk 251 and the ejector 253, respectively. At this time, one side of the load 252 may be mounted at a position eccentric from the rotation center of the disk 251.

  The ejector 253 is provided above the upper tray 110 and is axially coupled to the upper end of the load 252 so that it can be moved in the vertical direction by the operation of the drive unit 130. The ejector 253 connects a number of ejecting pins 253a corresponding to the number of the upper shells 115 formed on the upper tray 110 and the upper ends of the many ejecting pins 253a so that the plurality of ejecting pins 253a is one module. The connecting member 253b is configured to move as follows. And the upper end of the load 252 is rotatably connected to the end of the connecting member 253b.

  The ejecting pin 253a is mounted so as to penetrate above the upper plate tray 110, and the movement in the vertical direction is guided by an ejector guide 211 formed on the upper surface of the upper plate tray 110. The ejector guide 211 is formed in a circular shape, is extended by a predetermined length, and is formed such that the ejecting pin 253a can move in the vertical direction while being inserted inside the ejector guide 211.

  A part of the ejecting pin 253a passes through the air hole 116 formed in the upper shell 115 of the upper plate tray 110, and is formed so that the ice inside the upper shell 115 can be pushed downward. Of course, if necessary, at least a part of the upper shell 115 may be formed of an elastic member, and the lower end of the ejecting pin 253a can push the upper shell 115 from above to transfer the ice inside the upper shell 115. .

  Hereinafter, an ice maker ice transfer process according to the second embodiment of the present invention having the above-described configuration will be described.

  After the water for making ice is supplied to the lower plate tray 120, the lower plate tray 120 moves upward and maintains a state of being in close contact with the upper plate tray 110 as shown in FIG. In such a state, ice making is performed by cold air. At this time, the ejector 253 is positioned at the uppermost position, and the lower end of the ejecting pin 253a is positioned above the upper shell 115.

  When ice making is completed in such a state, first, the lower surface of the ice attached to the lower shell 122 is melted by driving the lower heater 152 so that the lower plate tray 120 and the ice are separated. In this state, the lower plate tray 120 is moved downward by driving the drive unit 130 to the state shown in FIG. 15, and after the lower plate tray 120 is completely moved downward, the lower plate tray 120 is rotated as shown in FIG. As a result, the lower part of the upper tray 110 is opened. At this time, the ice is hung on the upper shell 115 of the upper plate tray 110.

  On the other hand, when the lower plate tray 120 moves downward, the disk 251 connected to the drive shaft 132 also rotates, and the rotation of the disk 251 causes the load 252 to move up and down, causing the ejector 253 to move downward in the order of FIGS. To move.

  In the state of FIG. 16 in which the lower plate tray 120 is fully rotated, the lower end of the ejecting pin 253a penetrates the upper shell 115 and pushes the ice inside the upper shell 115 downward. Thus, the ice is separated from the upper plate tray 110 and transferred downward. Compared with the first embodiment in which the upper heater and the lower heater constitute the ejecting unit, in this embodiment, the difference is that the elements constituting the ejecting unit are the lower heater and the ejector. In the present embodiment, it is needless to say that the upper heater can be included in the component of the ejecting unit.

  The present invention can be applied to various embodiments other than the above-described embodiments, and a third embodiment of the present invention will be described below.

  In the third embodiment of the present invention, an ejecting unit is provided above the upper tray, and the ejecting unit can move the ice made by using the rack and pinion system in conjunction with the drive unit. It is characterized by being configured.

  Accordingly, the configuration of the ejecting unit and the other configurations except for the coupling relationship between the ejecting unit and the drive unit are all the same as in the first embodiment of the present invention described above, and the same reference numerals are used for the same configurations. Detailed description thereof will be omitted. Reference numerals not shown in the figure indicate the same reference numerals in the above-described embodiments.

  FIG. 17 is an exploded perspective view of an ice maker according to a third embodiment of the present invention, and FIGS. 18 to 20 are diagrams sequentially showing a state where ice is transferred from the ice maker.

  Referring to FIGS. 17 to 20, an ice maker 300 according to a third embodiment of the present invention includes an upper plate tray 110 having an upper shell 115, a lower plate tray 120 having a lower shell 122, and a lower plate. A drive unit 130 for moving and rotating the tray 120 in the vertical direction and an ejecting unit 350 for transferring the ice made to the outside of the tray member are included. The ejecting unit 350 includes an ejecting rack gear 351, an ejector 353, and a link 352.

  Specifically, the drive shaft 132 connected to the motor 131 is provided with a pinion gear 133 for driving the rack gear 140. An ejecting rack gear 351 is provided in front of the rack gear 140. The ejecting rack gear 351 is long in the vertical direction, and a pair is provided on both the left and right sides. The ejecting rack gear 351 is coupled to the pinion gear 133 so as to be vertically movable. Accordingly, an ejecting rack gear 351 is provided in front of the pinion gear 133 and a rack gear 140 is provided in the rear, and these are gear-coupled with the pinion gear 133 and interlock with each other when the pinion gear 133 rotates. Configured to be able to.

  A point 352c where the link 352 is located is rotatably coupled to a link mounting portion 311 formed on the upper surface of the upper plate tray 110 by a fastening member. Then, both ends of the link 352 are coupled to the ejecting rack gear 351 and the ejector 353, respectively. Accordingly, the link 352 can be rotated with the link mounting portion 311 as a reference by the vertical movement of the ejecting rack gear 351, and the ejector 353 can be moved up and down. In addition, a long sky 352a is formed at each end of the link 352, and the link 352 is smoothly rotated by being connected to the ejecting rack gear 351 and the ejector 353 by a connecting member 352b penetrating the long sky 352a.

  On the other hand, the ejector 353 may be provided above the upper plate tray 110 and may be configured to push and transfer ice formed inside the upper shell 115 formed on the upper plate tray 110. The ejector 353 may be attached to an ejecting guide 312 formed on the upper surface of the upper plate tray 110. The ejecting guide 312 is spaced apart in the front-rear direction and is formed to extend long in the up-down direction. Between these, the ejector 353 is positioned to guide the movement in the vertical direction.

  The ejector 353 includes ejecting pins 353a corresponding to the number of upper shells 115 and a connecting portion 353b that connects upper ends of the ejecting pins 353a. The lower portion of the ejecting pin 353a may be formed to have a diameter and a length that can pass through the air hole 116 of the upper shell 115. Of course, when the upper shell 115 is formed of a material that can be elastically deformed, even if the ejecting pin 353a does not penetrate the upper shell 115, the upper shell 115 may be pushed from above the upper shell 115 to transfer ice. Good. In this case, the diameter of the air hole must be smaller than the diameter of the lower end portion of the ejecting pin 353a.

  Hereinafter, an ice maker ice transfer process according to the third embodiment of the present invention will be described.

  After the water for making ice is supplied to the lower plate tray 120, the lower plate tray 120 moves upward and maintains a state of being in close contact with the upper plate tray 110 as shown in FIG. In this state, ice making is performed by cold air. At this time, the ejector 353 is positioned at the uppermost position, and the lower end of the ejecting pin 353a is positioned above the upper shell 115.

  When ice making is completed in such a state, the ice attached to the lower shell 122 is first melted by driving the lower heater 152 so that the lower tray 120 and the ice are separated. In this state, the lower plate tray 120 is moved downward by the drive of the drive unit 130 to be in a state as shown in FIG. Then, after the lower plate tray 120 has moved completely downward, it rotates as shown in FIG. 20 to open the lower portion of the upper plate tray 110. At this time, the ice is hung on the upper shell 115 of the upper plate tray 110.

  On the other hand, when the lower plate tray 120 moves downward, the ejecting rack gear 351 linked by the pinion gear 133 also moves upward. That is, when the pinion gear 133 rotates clockwise in the state shown in FIG. 18, the rack gear 140 moves downward, and the ejecting rack gear 351 moves upward to the state shown in FIG. In such a state, the ejector 353 is moved slightly downward and is not in contact with the ice provided in the lower spherical shell 103.

  In this state, when the pinion gear 133 further rotates clockwise to reach the state shown in FIG. 20, the rack gear 140 rotates to open the lower side of the upper plate tray 110, and the ejecting rack gear 351 moves upward. Further, the link 352 is further rotated clockwise so that the ejector 353 is moved further downward.

  In the state of FIG. 20 in which the lower plate tray 120 is fully rotated, the lower end of the ejecting pin 353a penetrates the upper shell 115 and pushes the ice inside the upper shell 115 downward. Thus, the ice is separated from the upper plate tray 110 and transferred downward.

  The present invention can be applied to various embodiments other than the above-described embodiments, and the fourth embodiment of the present invention will be described below.

  In the fourth embodiment of the present invention, an ejecting unit is provided above the upper tray, and the ejecting unit operates in a cam drive system in conjunction with driving of the drive unit so as to transfer ice produced. It is comprised by this.

  Accordingly, the configuration of the ejecting unit and the other configurations except for the coupling relationship between the ejecting unit and the drive unit are all the same as in the first embodiment of the present invention described above, and the same reference numerals are used for the same configurations. Detailed description thereof will be omitted. Reference numerals not shown in the figure indicate the same reference numerals in the above-described embodiments.

  FIG. 21 is an exploded perspective view of an ice maker according to a fourth embodiment of the present invention, FIG. 22 is a plan view showing the coupling relationship between the drive unit and the ejecting unit of the ice maker, and FIG. FIG. 24 to FIG. 26 are diagrams sequentially showing a state where ice is transferred from the ice maker.

  Referring to FIGS. 21 to 26, an ice maker 400 according to a fourth embodiment of the present invention includes an upper plate tray 110 having an upper shell 115, a lower plate tray 120 having a lower shell 122, and a lower plate tray. It includes a drive unit 130 that moves and rotates 120 in the vertical direction and an ejecting unit 450 that moves the ice made to the outside of the tray member. The ejecting unit 450 includes a cam gear 451, a shaft 452, a cam 453, and an ejector 454.

  Specifically, the cam gear 451 is mounted on both the left and right sides of the upper plate tray 110 and is connected by a shaft 452. The cam gear 451 may be provided between the side surface of the upper plate tray 110 and the rack gear 140. A cam gear housing portion 441 that is recessed outward is formed on the inner surface of the rack gear 140 corresponding to the position of the cam gear 451. The cam gear accommodating portion 441 is formed by recessing (or cutting) a part of the vertical portion 141 and the rotating portion 142 of the rack gear 140 so that the rack gear 140 is not interfered by the cam gear 451 while moving up and down.

  On the other hand, the cam gear 451 is configured to mesh with and interlock with the gear of the rotating portion 142 in a state where the rack gear 140 is moved downward for ice transfer. That is, the cam gear 451 does not rotate while the rack gear 140 moves up and down, but is configured to rotate together with the moment the rack gear 140 rotates for ice transfer.

  The shaft 452 is provided with a number of cams 453. The cam 453 is positioned above the upper shell 115. The shaft 452 is seated on a shaft seating portion 411 formed on the upper plate tray 110 and is mounted on the upper plate tray 110 in a rotatable state by a shaft fixing member 412.

  On the other hand, an ejector 454 is attached to the upper shell 115. The ejector 454 is mounted in a form inserted into the air hole 116, is elastically supported by the elastic member 455, and maintains a state where the upper surface is in contact with the cam 453 surface. Accordingly, when the cam gear 451 is not rotating, the ejector 454 protrudes upward. When the cam gear 451 is rotated, the ejector 454 is pushed by the cam 453 surface, and the ice inside the upper shell 115 is Can be pushed downward.

  Hereinafter, an ice maker ice transfer process according to the fourth embodiment of the present invention will be described.

  After water for making ice is supplied to the lower plate tray 120, the lower plate tray 120 moves upward and maintains a state of being in close contact with the upper plate tray 110 as shown in FIG. In this state, ice making is performed by cold air. At this time, the ejector 454 is supported by the elastic member 455 and is positioned at the uppermost position.

  When ice making is completed in such a state, the lower surface of the ice is first melted by driving the lower heater 152 so that the ice can be separated from the lower plate tray 120. In this state, the lower plate tray 120 is moved downward by driving the drive unit 130 to a state as shown in FIG. 25, and after the lower plate tray 120 is completely moved downward, as shown in FIG. By rotating, the lower part of the upper plate tray 110 is opened. At this time, the ice is hung on the upper shell 115 of the upper plate tray 110. The cam gear 451 is positioned inside the cam gear accommodating portion 441 while the rack gear 140 moves in the vertical direction, and does not interfere with the rack gear 140.

  On the other hand, when the cam gear 451 starts to rotate with the lower plate tray 120 moved completely downward as shown in FIG. 25, the cam gear 451 is coupled with the rack gear 140 to rotate. Specifically, when the pinion gear 133 rotates clockwise in the state shown in FIG. 25, the pinion gear 133 is gear-coupled with the rotating portion 142 of the rack gear 140 and rotates the rack gear 140 counterclockwise.

  When the rack gear 140 is rotated counterclockwise, the cam gear 451 is rotated clockwise, and the cam 453 mounted on the shaft 452 is also rotated. When the rack gear 140 is completely rotated as shown in FIG. 26, the ejector 454 is pushed by the surface of the cam 453 as shown in FIG. 22 and pushes the ice hanging inside the upper shell 115 downward. The produced ice is forcibly separated from the upper plate tray 110 and transferred to the lower side.

  The present invention can be applied to various embodiments other than the above-described embodiments, and the fifth embodiment of the present invention will be described below.

  In the fifth embodiment of the present invention, an ejecting unit is provided in front of the upper tray, and when the upper tray is rotated after being moved upward, the ejecting unit is inserted into the upper tray to transfer ice. It is configured to obtain.

  FIG. 27 is a perspective view of an ice maker according to a fifth embodiment of the present invention, and FIGS. 28 to 31 are diagrams sequentially showing a state where ice is transferred from the ice maker of the present invention.

  27 to 31, an ice maker 500 according to a fifth embodiment of the present invention includes a tray composed of an upper plate tray 510 and a lower plate tray 520, a drive unit 530 for opening and closing the tray, and a tray. The ejecting unit 550 is configured to transfer ice made from the inside of the apparatus.

  Unlike the previous embodiments, in this embodiment, the lower plate tray 520 is fixedly mounted on the side wall of the ice maker case 501 or the freezer compartment 4, and the lower plate tray 520 has a number of lower shells 521 that are recessed in a hemispherical shape. Are continuously arranged. The lower shell 521 is in close contact with the upper shell 511 formed on the upper plate tray 510 to form a shell that makes spherical ice.

  The lower plate tray 520 may be formed of a metal material, and the lower plate tray 520 is provided with a heater 522 to heat the lower plate tray 520 when ice is transferred to facilitate ice transfer.

  The upper plate tray 510 is provided above the lower plate tray 520 and is configured to be movable up and down and rotated by the drive unit 530. The upper plate tray 510 is formed in a shape in which a large number of cylinders are connected, and is formed so that the upper surface is opened. The lower surface is formed to be recessed upward by the upper shell 511. The upper shell 511 may be formed of a material that can be elastically deformed, and an air hole may be further formed on the upper surface. The upper plate tray 510 is configured to be inserted into the lower plate tray 520 when moved downward.

  The drive unit 530 is for vertically moving and rotating the upper plate tray 510, and includes a motor 531, a rack gear 540, and a pinion gear 532.

  Specifically, the rack gear 540 is provided on both the left and right sides of the upper plate tray 510 and includes a vertical portion extending upward and a rotating portion 542 extending laterally from the lower end of the vertical portion 541. A gear that meshes with the pinion gear 532 is formed on the rear side surface (the right side in FIG. 28) of the rack gear 540. Therefore, when the pinion gear 532 rotates, the rack gear 540 can move up and down and rotate.

  A guide groove 543 is formed on the outer surface of the rack gear 540, and a guide protrusion 544 formed on the case 501 is interposed in the guide groove 543. Since the structure of the guide groove 543 and the guide protrusion 544 is the same as that of the first embodiment described above, the detailed structure thereof is omitted.

  On the other hand, the ejecting unit 550 is for transferring ice attached to the upper plate tray 510 and is provided in front of the upper plate tray 510. The ejecting unit includes an insertion portion 551, a pushing portion 552, a connecting portion 553, and a rotating shaft portion 554.

  The insertion portion 551 and the pushing portion 552 are formed to extend downward and have a U shape by the connecting portion 553. The insertion unit 551 transfers the ice that has been inserted into the upper surface of the upper plate tray 510 and made into ice when the upper plate tray 510 rotates. Then, the pushing portion 552 pushes the outside of the upper plate tray 510 in a state where the insertion portion 551 is inserted into the upper plate tray 510 so that the ejecting unit 550 does not shake. Further, on both the left and right sides of the connecting portion 553, a rotating shaft portion 554 that extends the ejecting unit 550 rotatably is formed. The rotation shaft portion 554 is attached to the case 501, and the push portion 552 is inclined so as to be closer to the insertion portion 551 toward the end portion.

  The rotating shaft portion 554 may be positioned further above the rotating shaft of the lower plate tray 520, that is, the rotating shaft of the pinion gear 532. In a state where the upper plate tray 510 does not rotate, the lower end of the insertion portion 551 is positioned further above the upper surface where the upper plate tray 510 is opened. A large number of insertion portions 551 are formed so as to push the respective upper shells 511, the number corresponding to the number of the upper shells 511 is formed, and they are arranged at equal intervals.

  Hereinafter, an ice maker ice transfer process according to the fifth embodiment of the present invention will be described.

  In order to make ice on the lower plate tray 520, after the water for making ice is supplied to the lower shell 521, the upper plate tray 510 moves downward while the lower plate tray 520 is fixed. The lower end of the upper plate tray 510 moved downward is inserted into the lower plate tray 520 as shown in FIG. 28, and the upper shell 511 and the lower shell 521 come into contact with each other to make spherical ice.

  When ice making is completed in such a state, the lower surface of the ice made in contact with the lower shell 521 is first melted by driving the lower heater 522 so that the ice is separated from the lower plate tray 520. In this state, the upper tray 510 is linearly moved upward by the drive of the drive unit 530, and the state shown in FIG. 29 is obtained. When the upper plate tray 510 is raised to the uppermost position, the end portion of the insertion portion 551 is positioned immediately above the upper shell 510.

  When the pinion gear 532 further rotates in the state shown in FIG. 29, the rack gear 540 starts to rotate clockwise. As the rack gear 540 rotates, the upper plate tray 510 also rotates clockwise.

  At the same time, as shown in FIG. 30, a part of the insertion portion 551 is naturally inserted into the opened upper surface of the upper plate tray 510. Then, while the upper plate tray 510 rotates, the front surface portion of the upper plate tray 510, specifically, the front surface portion of the cylindrical portion comes into contact with the push portion 552. When the upper plate tray 510 further rotates in such a state, the ejecting unit 550 also rotates together. As a result, the pushing portion 551 is further inserted into the upper plate tray 510 while rotating. Then, the end of the pushing portion 551 pushes the upper shell 511 of the upper plate tray 510 so that the ice is separated.

  As shown in FIG. 31, when the upper plate tray 510 is completely rotated, the insertion portion 551 pushes the upper shell 511 from above, and the ice inside the upper shell 511 is transferred to the outside.

  The present invention can be applied to various embodiments other than the above-described embodiments, and the sixth embodiment of the present invention will be described below.

  FIGS. 32 to 34 are views sequentially showing the state where ice is transferred from the ice maker according to the sixth embodiment of the present invention.

  Referring to FIGS. 32 to 34, an ice maker 600 according to a sixth embodiment of the present invention includes a tray composed of an upper plate tray 610 and a lower plate tray 620 that form a shell for making spherical ice, A drive unit (not shown) for opening and closing the tray, and an ejecting unit 640 for transferring ice made from the inside of the tray are included.

  The lower plate tray 620 is fixedly attached to one side of the case or the cabinet. A large number of lower shells 622 that are recessed in a hemispherical shape are continuously arranged on the lower plate tray 620. The lower shell 622 is in close contact with the upper shell 612 formed on the upper plate tray 610 to form a spherical shell.

  The lower plate tray 620 may be formed of a metal material, and the lower plate tray 620 is equipped with a heater 626 to heat the lower plate tray 620 when ice is transferred to facilitate ice transfer.

  Meanwhile, a frame 630 extending vertically upward is formed on the rear surface of the lower plate tray 620. The frame 630 has a predetermined height. An ejecting pin 641 which is one component of the ejecting unit 640 is formed on the upper surface of the frame 630. The ejecting pin 641 is formed to extend downward from the bottom surface of the plate 643 that extends forward from the upper surface of the frame by a predetermined length.

  The upper plate tray 610 is provided above the lower plate tray 620 and can be moved up and down by a drive unit. The upper tray 610 is formed in a shape in which a number of cylinders are connected, and is formed so that the upper surface is opened, and the upper shell 612 is formed on the lower surface. The upper shell 612 may be formed of a material that can be elastically deformed, and an air hole penetrating the upper shell 612 may be further formed at the upper end of the upper shell 612. A water chamber 624 is formed on the upper surface of the lower shell 622, and water is added to the water chamber 624. The water added to the water chamber 624 flows into the upper shell 612 while the upper shell 612 is in close contact with the lower shell 622. This is the same as described in the first embodiment.

  The upper plate tray 610 is configured to be inserted into the lower plate tray 620 when moved downward. At this time, the upper shell 612 is coupled to the lower shell 622 to form a spherical shell.

  On the other hand, a drive unit for moving the upper plate tray 610 in the vertical direction is not shown in detail, but a pinion gear is mounted on a general motor, a rack gear is mounted on the upper plate tray 610, and the upper plate tray 610 is mounted. May be configured to move up and down.

  The frame 630 may include an ice transfer guide 642 that guides ice transferred from the upper plate tray 610 to the front of the lower plate tray 620. The ice transfer guide 652 constitutes an ejecting unit 640 together with the ejecting pin 641 and is rotatably mounted at a certain point of the frame 630.

  Specifically, the ice transfer guide 642 is formed in a bar or plate shape having a predetermined length, and the rotation shaft of the ice transfer guide 642 is provided with an elastic member 642a such as a torsion spring in a state where no external force is applied. As shown in FIG. 32, it is in a state of being rotated forward by a predetermined angle, and is configured to be able to shield at least a part of the front of the lower plate tray 620.

  When the upper plate tray 610 moves downward, the ice transfer guide 642 is pressurized by the rear side surface of the upper plate tray 610 and maintains a state of being in close contact with the front surface of the frame 630. The frame 630 may be formed with a stopper 631 that limits the rotation angle of the ice transfer guide 642. Therefore, the rotation of the ice transfer guide 642 may be limited by the stopper 631, and in such a state, the ice falling with the ice transfer guide 642 tilted is guided so as to be moved forward.

  The operation of the ice maker according to the sixth embodiment of the present invention having the above configuration will be described below.

  First, the upper plate tray 610 moves upward, and water for making ice is supplied to the lower shell 622 with the upper surface of the lower plate tray 620 opened. After an amount of water set to fill the shell is supplied, the upper plate tray 610 moves downward. When the lower portion of the upper plate tray 610 is inserted into the water chamber 624 of the lower plate tray 620 and moved completely downward, the state shown in FIG. 32 is obtained.

  In such a state, the upper shell 612 and the lower shell 622 are completely brought into close contact with each other, and the water added to the inside of the spherical shell is frozen. After a predetermined time, the water inside the shell is completely frozen to form spherical ice. The

  On the other hand, when ice making is completed, the heater 626 attached to the lower plate tray 620 in the state shown in FIG. 32 is driven for ice transfer. The lower plate tray 620 is heated by the driving of the heater 626, and the surface of ice in contact with the lower shell 622 is melted so that the lower plate tray 620 is easily separated. The ice transfer guide 642 is in close contact with the frame 630 while being pushed by the upper plate tray 610, and the elastic member 642a is maintained in a compressed state.

  When the operation of the heater 626 is completed, the upper plate tray 610 moves upward. When the upper plate tray 610 moves upward, the produced ice is moved upward while being attached to the upper shell 612, resulting in a state as shown in FIG.

  In this way, when the upper plate tray 610 or ice is moved above the ice transfer guide 642, the external force applied to the ice transfer guide 642 is removed, and the ice transfer guide 642 rotates clockwise by the restoring force of the elastic member 642a. It will be spread while.

  In the state where the ice transfer guide 642 is fully expanded as shown in FIG. 33, the rear end of the ice transfer guide 642 is supported by the support portion 631 formed on the frame 630, and the ice transfer guide 642 is maintained in an inclined state. To get.

  On the other hand, when the upper plate tray 610 moves further upward in the state as shown in FIG. 32, the ejecting pin 641 comes into contact with the upper shell 621, and in the state where the upper plate tray 610 is moved to the uppermost position, as shown in FIG. Thus, the ejecting pin 641 pushes the upper shell 612 from above.

  Since the upper shell 612 is formed of a material that can be elastically deformed, the upper shell 612 is deformed by the ejecting pin 641, and the ice attached to the upper shell 612 falls downward. The spherical ice falling from the upper plate tray 610 comes into contact with the ice transfer guide 642, is moved along the ice transfer guide 642, and is moved to the front of the lower plate tray 620. Therefore, the ice that has been made can be stored in an ice bank or the like that is completely separated from the ice maker 600.

  After the ice is transferred in such a process, water supply starts again, and the above process is repeated to continuously produce ice.

Claims (7)

A tray member including an upper plate tray having an upper shell, and a lower plate tray having a lower shell that is in close contact with the upper shell to form a spherical shell;
A water supply unit provided in the upper plate tray for supplying water;
A water supply guide portion provided in the lower plate tray for guiding water supplied from the water supply unit to the lower shell;
It is provided on one side of the tray member, and either one of the upper plate tray and the lower plate tray is separated from the other one, or any one is in close contact with the other one. A drive unit that provides power for
An ejecting unit provided on one side of the tray member for separating ice formed inside the spherical shell,
The drive unit is
A motor that provides rotational force;
A pinion gear coupled to the rotating shaft of the motor;
A rack gear that is provided on a side surface portion of the lower plate tray and moves the lower plate tray by meshing with the pinion gear;
The rack gear is
A vertical portion for moving the lower plate tray up and down;
A rotating part that curves with a predetermined curvature from the upper end of the vertical part and rotates the lower plate tray,
The ejecting unit is
A heater mounted on the outer peripheral surface of the lower plate tray;
A rod-like ejector that moves vertically and separates the ice attached to the upper shell through the upper shell;
Power conversion means for converting rotational force transmitted from the pinion gear into linear motion of the ejector,
During the ice transfer process,
The upper tray is kept fixed,
The rack gear is lowered and rotated by the rotation of the pinion gear to lower and rotate the lower plate tray,
The ice maker is characterized in that, when the lower plate tray is lowered and rotated, the ejector separates ice adhering to the upper shell through the upper shell . A guide groove formed on a side surface of the rack gear;
The tray member protrudes from a side surface of the case which housed further including a guide projection to be fitted in the guide groove, ice maker according to claim 1. Further comprising a guide roller in contact with a surface of the rack gear opposite the surface that meshes with the pinion gear, ice maker according to claim 1. The power conversion means is
A disk to which a rotational force is transmitted from the rotation shaft of the motor;
A load having one end connected to the disk and the other end connected to the ejector ;
Including, ice maker according to claim 1. The power conversion means is
An ejecting rack gear that meshes with the pinion gear and moves up and down;
One end connected to the the ejecting rack gear, and links the other end Ru is connected to the ejector,
Including, ice maker according to claim 1. The ice maker according to claim 5 , wherein a point where the link is located is rotatably connected to the upper plate tray. The power conversion means is
A cam gear gear-coupled to the rotating part at a point where the rack gear starts to rotate after being linearly lowered ;
Connected to a rotary shaft of the cam gear, a cam Ru lowers the ejector while rotating,
Including, ice maker according to claim 1.

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